JP2021062073A - Catheter and oxygen partial pressure measuring method - Google Patents

Abstract

To provide a catheter capable of easily measuring an oxygen partial pressure.SOLUTION: A catheter comprises a catheter main body 10 and a probe 20 for measuring an oxygen partial pressure. The catheter main body has a structure where a vertical hole, through which the probe can pass in an axial center direction Z of the catheter main body, is formed in a tip end 11. This structure allows an operator to position the probe at an appropriate position in urine 31 in a bladder 30 merely by slidably moving the probe after the catheter main body is inserted into the bladder, which makes it possible to easily measure an oxygen partial pressure.SELECTED DRAWING: Figure 1

Description

The present invention relates to a catheter capable of measuring an oxygen partial pressure and a method for measuring an oxygen partial pressure.

Acute kidney injury (AKI), which occurs in 30 to 50% of hospitalized patients in the intensive care unit, adversely affects the prognosis of patients even if it is mild, and requires blood purification. The mortality rate in cases is as high as 60%. In addition, the transition to chronic renal failure has also become a problem. Hypoxia in the renal medulla is one of the causes of AKI, and it is considered that the partial pressure of renal medulla oxygen can be estimated by measuring the partial pressure of urinary oxygen in the bladder. In order to measure the oxygen partial pressure in urine in the bladder, a urinary tract catheter has been proposed in which an oxygen partial pressure measuring sensor is projected from the side hole of the urinary bladder to measure the oxygen partial pressure in the bladder or the bladder wall. (See, for example, Patent Documents 1 and 2).

Japanese Patent No. 2739880 International Publication No. 2018/083487

However, in the urethral catheter according to the above-mentioned conventional technique, since the oxygen partial pressure measurement sensor is projected from the side of the catheter body, the oxygen partial pressure sensor may damage the urethra when the urethral catheter is inserted, and the oxygen partial pressure may be damaged. There was a risk that it could not be measured properly.

In addition, since the path inside the catheter body through which the oxygen partial pressure measurement sensor passes is bent near the tip of the catheter body, the oxygen partial pressure sensor is easily caught at this bent position, and the tip of the oxygen partial pressure sensor is attached to the catheter body. It was difficult to project from.

Even if the oxygen partial pressure measurement sensor is located on the tip side of the catheter body, if the opening hole at the tip of the catheter is only the (horizontal hole) side hole, thrombi etc. may be clogged or urine may accumulate. It was difficult to measure an appropriate partial pressure of oxygen.

An object of the present invention is to solve the above-mentioned problems of the prior art and to provide a catheter capable of easily measuring the oxygen partial pressure.

The present invention includes a catheter body and a probe for measuring oxygen partial pressure, and the catheter body has a vertical hole (tip hole) formed at the tip thereof in the axial direction of the catheter body through which the probe can penetrate. It is characterized by being done.

In this case, the inner circumference of the vertical hole (tip hole) of the catheter may be the same as or shorter than the inner circumference of the flow path of the catheter body. The catheter body may have a lateral hole (side hole) formed in the vicinity of the tip thereof. The inner circumference of the vertical hole (tip hole) of the catheter body may be the same as or shorter than the inner circumference of the lateral hole (side hole).

Further, the present invention includes a catheter main body and a probe for measuring oxygen partial pressure, and the catheter main body is formed with a vertical hole at the tip thereof through which the probe can penetrate in the axial direction of the catheter main body. The method for measuring the partial pressure of oxygen using a catheter is characterized by having a step of inserting the catheter body into the bladder and a step of penetrating the probe through the vertical hole.

Further, the present invention includes a catheter main body and a probe for measuring oxygen partial pressure, and the catheter main body is formed with a vertical hole at the tip thereof through which the probe can penetrate in the axial direction of the catheter main body. In the method for measuring the partial pressure of oxygen using a catheter, a step of inserting the catheter body in which the probe protrudes from the vertical hole into the bladder and a step of measuring the partial pressure of oxygen in urine using the probe. It is characterized by having.

Furthermore, the present invention includes a catheter body and a probe for measuring oxygen partial pressure, and the catheter body is formed with a vertical hole at the tip thereof through which the probe can penetrate in the axial direction of the catheter body. Further, in the method of measuring the partial pressure of oxygen using a catheter, a step of inserting the catheter body into the bladder and a step of measuring the partial pressure of oxygen in urine flowing into the body of the catheter using the probe are performed. It is characterized by having.

In the present invention, it is possible to provide a catheter capable of easily measuring the partial pressure of oxygen.

It is a schematic diagram which shows the state that the urethral balloon catheter was inserted into the bladder. It is a front view which shows the tip of the urethral balloon catheter. It is sectional drawing which shows typically the tip of the urethral balloon catheter. It is a schematic diagram which shows the urethral balloon catheter which concerns on the modification. It is sectional drawing which shows typically the tip of the urethral balloon catheter which concerns on the modification.

Hereinafter, a urethral balloon catheter according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic view showing a state in which a urethral balloon catheter is inserted into a bladder.

As shown in FIG. 1, the urethral balloon catheter 100 includes a catheter body 10 and a probe 20.

The catheter body 10 is formed in a tubular shape so that fluid can flow inside and the probe 20 can pass through. The catheter body 10 according to the present embodiment is made of silicon rubber, but may be made of latex, natural rubber, isoprene rubber, thermoplastic resin, for example, PVC and urethane rubber, fluororubber, fluororesin, or the like. Good. The catheter body 10 is provided with a balloon 12 in the vicinity of the tip 11, and the catheter body is fixed in the bladder 30 by inflating the balloon 12 while being inserted into the bladder 30.

The catheter body 10 is provided with a branch connector 17. Although the branch connector 17 is made of silicon rubber, it may be made of latex, natural rubber, isoprene rubber, thermoplastic resin, for example, PVC and urethane rubber, fluororubber, fluororesin, and the like. Further, the branch connector 17 is provided with a gas or liquid such as a pipe line 17a through which the root portion of the probe 20 penetrates, a discharge pipe line 17b for discharging urine 31 flowing from the bladder 30, and air or sterilized water. A delivery conduit 17c for sending and inflating the balloon 12 is provided. The delivery line may be equipped with a one-way valve, to which a syringe can be connected. Further, the conduit through which the root portion of the probe 20 penetrates may have a function of adjusting the insertion depth of the probe 20. As the adjusting function, the insertion depth of the probe 20 may be adjusted by, for example, a bellows type, a screw type (dial type), or a circumferential rib is formed in the conduit.

The probe 20 incorporates a fluorescent optode (optical electrode) that measures the intensity of light emitted from the fluorescent dye that has reacted with urine 31 in the bladder 30, a dual fiber laser Doppler probe, and a temperature sensor. The probe 20 can measure the partial pressure of oxygen in urine. Further, the probe 20 may be coated in order to reduce friction with the cavity of the catheter body 10. As the coating agent, for example, a material such as Teflon coat, parylene, or a hydrophilic polymer that can reduce friction with the cavity of the cartel body 10 may be used. The above-mentioned coating agent may be treated on the lumen side of the catheter body 10.

Hereinafter, the urethral balloon catheter 100 will be described in more detail.
FIG. 2 is a front view showing the tip of the urethral balloon catheter, and FIG. 3 is a cross-sectional view showing the tip of the urethral balloon catheter. In FIG. 3, FIG. 3A shows a state in which the probe 20 is housed in the catheter body 10, and FIG. 3B shows a state in which the probe 20 protrudes from the catheter body.

As shown in FIG. 2, the catheter body 10 is configured by combining a tube portion 10a and an insertion end 10b. As shown in FIG. 3, the catheter body 10 is for circulating urine 31 stored in the bladder 30 in the vicinity of the tip 11, that is, between the tip 11 and the balloon 12 (see FIG. 1). A pair of lateral holes (side holes) 13 are formed. The pair of lateral holes (side holes) 13 are located so as to face each other, and are formed so as to penetrate the wall portion 15 of the catheter main body 10 in a direction perpendicular to the axial direction Z, respectively. The pair of lateral holes (side holes) 13 are formed so as to have an elongated hole shape extending in the axial direction Z. Further, it is desirable that two lateral holes (side holes) 13 are formed, but this is not the case.

A vertical hole (tip hole) 14 is formed at the tip 11 of the catheter body 10. The vertical hole (tip hole) 14 has a substantially perfect circular shape and is formed so as to penetrate the tip 11 in the axial direction Z. That is, the vertical hole (tip hole) 14 penetrates the tip 11 of the catheter body 10 in a direction perpendicular to the direction in which the pair of horizontal holes (side holes) 13 penetrate the catheter body 10. This vertical hole (tip hole) may be a tip having an obtuse angle by polishing the tip of the catheter body, or only the tip may be formed by mold molding and adhered to the catheter body. ..

The inner circumference of the vertical hole (tip hole) 14 is formed so as to be the same as or shorter than the inner circumference of the flow path 16 passing through the inside of the catheter body 10. That is, the opening area of the vertical hole (tip hole) 14 is the same as or smaller than the opening area of the flow path 16. Further, the inner circumference of the vertical hole (tip hole) 14 is formed longer than the outer circumference of the probe 20. As a result, the probe 20 can be slidably moved so as to penetrate the vertical hole (tip hole) 14. At this time, in the catheter main body 10, the vertical hole (tip hole) 14 may have a substantially perfect circular shape, and the inner circumference of the vertical hole (tip hole) 14 may have substantially the same length as the outer circumference of the probe. It is possible to prevent the probe 20 from moving in a direction perpendicular to the central direction Z.

The insertion end 10b of the catheter body 10 has an inclined portion 18 whose inner peripheral surface is formed in a conical shape. The inclined portion 18 is formed so that the angle between the inclined portion 18 and the axial direction Z is an acute angle with respect to the outer peripheral surface of the insertion end 10b. As a result, when the probe 20 is pushed toward the tip 11, the probe 20 is guided by the inclined portion 18 and can easily penetrate the vertical hole 14.

Since a gap is formed between the flow path 16 and the probe 20 in the catheter body 10, urine 31 can flow through this gap. In the catheter body 10, the flow path 16 and the probe 20 may be formed in separate conduits.

Hereinafter, a procedure for measuring the oxygen partial pressure of urine 31 in the bladder 30 using the urethral balloon catheter 100 will be described.

When measuring the oxygen partial pressure of urine 31 in the bladder 30 using the urethral balloon catheter 100, the operator first takes out the urethral balloon catheter 100 from a bag-shaped package (not shown). At this time, the urethral balloon catheter 100 is housed in the package with the probe 20 preliminarily incorporated in the catheter body 10 so that the probe 20 does not protrude from the tip 11 of the catheter body 10.

When the urethral balloon catheter 100 is removed from the package, the operator inserts the tip 11 of the urethral balloon catheter 100 into the bladder 30 through the urethra. At this time, the probe 20 is retracted into the catheter body 10 so that the probe 20 does not protrude outward from the tip 11 of the urethral balloon catheter 100 through the vertical hole (tip hole) 14.

When the tip 11 of the urethral balloon catheter 100 is inserted into the bladder 30, the operator connects the syringe to the one-way valve 17a connected to the branch connector 17 and inflates the balloon 12. As a result, the urethral balloon catheter 100 is fixed in the bladder 30.

When the urethral balloon catheter 100 is fixed in the bladder 30, the operator slides the probe 20 toward the tip 11 of the catheter body 10 in the flow path 16 by pushing the root of the probe 20 into the branch connector 17. It is moved so that the tip of the probe 20 penetrates through the vertical hole (tip hole) 14.

When the tip of the probe 20 is passed through the vertical hole (tip hole) 14, the probe 20 comes into contact with the urine 31 stored in the bladder 30 and the oxygen partial pressure of the urine 31 can be measured. At this time, the urine 31 in the bladder 30 flows into the catheter body 10 from the pair of lateral holes (side holes) 13 and then flows through the gap between the flow path 16 and the probe 20 to the branch connector. It is designed to be stored in a connected urine bag (not shown).

However, as described above, the probe 20 may not penetrate the vertical hole (tip hole) 14 and the probe 20 may be installed in the catheter body, and the urine stored in the bladder 30 is the vertical hole (tip hole). Since it flows into the flow path 16 of the catheter body 10 from the hole) 14 or the lateral hole (side hole) 13, the partial pressure of oxygen in urine can be measured.

The urethral balloon catheter 100 according to the present embodiment includes a catheter body 10 and a probe 20 for measuring oxygen partial pressure, and the catheter body 10 is capable of penetrating the probe 20 in the axial direction Z of the catheter body 10. A vertical hole (tip hole) 14 is formed at the tip 11. As a result, the operator can position the probe 20 at an appropriate position in the urine 31 in the bladder 30 simply by sliding the probe 20 after inserting the catheter body 10 into the bladder 30. The partial pressure can be easily measured.

Further, since the probe 20 projects from the vertical hole (tip hole) 14 of the catheter body 10 in the axial direction Z, the oxygen partial pressure of the urine 31 in the ureter 32 is measured by inserting the probe 20 into the ureter 32. You can also do it.

Although one embodiment of the present invention has been described above, the above-described embodiment of the present invention is for facilitating the understanding of the present invention and does not limit the present invention. The present invention can be modified and improved without departing from the spirit of the present invention, and the present invention includes equivalents thereof. For example, in the above embodiment, the urethral balloon catheter 100 inserted into the bladder 30 is described, but the present invention is not limited to this, and a catheter used at other sites, for example, a catheter inserted into the upper urinary tract. The present invention may be applied.

Further, in the above embodiment, the user allows the probe 20 to penetrate through the vertical hole 14 to adjust the insertion depth of the probe 20, but the present invention is not limited to this. For example, the probe 20 may be housed in the package in a state of penetrating the vertical hole 14 in advance so that the user does not have to adjust the insertion depth.

Further, in the above embodiment, the oxygen partial pressure of urine 31 outside the urethral balloon catheter 100 is measured by using the probe 20 penetrating through the vertical hole 14, but the present invention is not limited to this. For example, if the tip of the probe 20 is held in the catheter body 10 and the oxygen partial pressure in the urine 31 can be measured, the oxygen partial pressure of the urine 31 flowing into the catheter body 10 from the vertical hole 14 or the horizontal hole 13 is measured. May be good.

Furthermore, in the above embodiment, the branch connector 17 integrally includes a conduit 17a through which the probe 20 penetrates, a discharge conduit 17b for discharging urine 31, and a delivery conduit 17c for delivering air and the like. Although provided, the invention is not limited to this. For example, the branch connector is divided into two parts, and a portion provided with a conduit 17a through which the probe 20 penetrates and a discharge conduit 17b for discharging urine 31 behind the portion provided with the delivery conduit 17c. It may be a branch connector in which the above are combined.

Further, in the above embodiment, the urethral balloon catheter 100 has an inclined portion 18 having a conical shape, but the present invention is not limited thereto. For example, as shown in FIG. 5 (a), the inner peripheral surface of the tip 11 is an inclined portion 19 having a hemispherical shape and the wall thickness is made uniform, and as shown in FIG. 5 (b), it has a hemispherical shape. It may be guided by the inclined surface 19 and penetrate the vertical hole 14.

10 ... Catheter body 11 ... Tip 12 ... Balloon 13 ... Lateral hole (side hole)
14 ... Vertical hole (tip hole)
15 ... Wall 16 ... Flow path 17 ... Branch connector 18 ... Tilt 19 ... Tilt 20 ... Probe 30 ... Bladder 31 ... Urine 32 ... Ureter 100 ... Urethral balloon catheter Z ... Axial direction

Claims (7)

Catheter body and
Equipped with a probe for measuring oxygen partial pressure,
The catheter body is a catheter characterized in that a vertical hole through which the probe can penetrate is formed at the tip in the axial direction of the catheter body. The catheter according to claim 1, wherein the inner circumference of the longitudinal hole (tip hole) of the catheter is the same as or shorter than the inner circumference of the flow path of the catheter body. The catheter according to claim 1 or 2, wherein the catheter body has a lateral hole formed in the vicinity of the tip thereof. The catheter according to claim 3, wherein the inner circumference of the vertical hole of the catheter body is shorter than the inner circumference of the horizontal hole. An oxygen using a catheter is provided with a catheter body and a probe for measuring oxygen partial pressure, and the catheter body has a vertical hole formed at the tip in the axial direction of the catheter body through which the probe can penetrate. In the partial pressure measurement method
The step of inserting the catheter body into the bladder and
A step of penetrating the probe through the vertical hole,
The step of measuring the partial pressure of oxygen in urine using the probe,
A method for measuring an oxygen partial pressure. An oxygen using a catheter is provided with a catheter body and a probe for measuring oxygen partial pressure, and the catheter body has a vertical hole formed at the tip in the axial direction of the catheter body through which the probe can penetrate. In the partial pressure measurement method
The step of inserting the catheter body in which the probe protrudes from the vertical hole into the bladder,
The step of measuring the partial pressure of oxygen in urine using the probe,
A method for measuring an oxygen partial pressure. An oxygen using a catheter is provided with a catheter body and a probe for measuring oxygen partial pressure, and the catheter body has a vertical hole formed at the tip in the axial direction of the catheter body through which the probe can penetrate. In the partial pressure measurement method
The step of inserting the catheter body into the bladder and
A step of measuring the partial pressure of oxygen in urine flowing into the catheter body using the probe, and
A method for measuring an oxygen partial pressure.

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